Switching on microglia with electro-conductive multi walled carbon nanotubes

We explored the mechanisms underlying microglia cell-carbon nanotube interactions in order to investigate whether electrical properties of Carbon-Nanotubes (CNTs) could affect microglia brain cells function and phenotype. We analyzed the effects induced by highly electro-conductive Multi-Walled-Carbon-Nanotubes (a-MWCNTs), on microglia cells from rat brain cortex and compared the results with those obtained with as prepared not conductive MWCNTs (MWCNTs) and redox-active Double-Walled-Carbon-Nanotubes (DWCNTs). Cell viability and CNT capacity to stimulate the release of nitric oxide (NO), pro-inflammatory (IL-1b, TNF-a) and anti-inflammatory (IL-10, TGF-b1) cytokines and neurotrophic factors (mNGF) were assessed. Electro-conductive MWCNTs, besides not being cytotoxic, were shown to stimulate, at 24 h cell exposure, classical "M100 microglia activation phenotype, increasing significantly the release of the main pro-inflammatory cytokines. Conversely, after 48 h cell exposure, they induced the transition from classical "M100 to alternative "M200 microglia phenotype, supported by anti-inflammatory cytokines and neuroprotective factor mNGF release. The analysis of cell morphology change, by tubulin and CD-206 þ labelling showed that M2 phenotype was much more expressed at 48 h in cells exposed to a-MWCNTs than in untreated cells. Our data suggest that the intrinsic electrical properties of CNTs could be exploited to modulate microglia phenotype and function stimulating microglia anti-inflammatory potential

A comparative study on the enzymatic biodegradability of covalently functionalized double- and multi-walled carbon nanotubes

The assessment of the biodegradability potential of carbon nanotubes (CNTs) is a fundamental point towards their applications in materials science and biomedicine. Due to the continuous concerns about the fate of such type of nanomaterials, it is very important to understand if they can undergo degradation under certain conditions and if the morphology and structure of the nanotubes play a role in this process. For this purpose we have decided to undertake a comparative study on the enzymatic degradation of CNTs with concentric multilayers. Double-walled (DW) and multi-walled (MW) CNTs of various lengths, degrees of oxidation and functionalizations using different methods were treated with horseradish peroxidase (HRP). While all tested DWCNTs resulted resistant to the biodegradation, some of the MWCNTs were partially degraded by the enzyme. We have found that short oxidized multi-walled CNTs functionalized by amidation were reduced in length and presented a high amount of defects at the end of the period of treatment with HRP. This comparative study holds its importance in the understanding of the structural changes of different types of nanotubes towards the catalytic enzymatic degradation and will help to design safer CNTs for future applications

Examining the impact of multi-layer graphene using cellular and amphibian models

In the last few years, graphene has been defined as the revolutionary material showing an incredible expansion in industrial applications. Different graphene forms have been applied in several contexts, spreading from energy technologies and electronics to food and agriculture technologies. Graphene showed promises also in the biomedical field. Hopeful results have been already obtained in diagnostic, drug delivery, tissue regeneration and photothermal cancer ablation. In view of the enormous development of graphene-based technologies, a careful assessment of its impact on health and environment is demanded. It is evident how investigating the graphene toxicity is of fundamental importance in the context of medical purposes. Onthe other hand, the nanomaterial present in the environment, likely to be generated all along the industrial life-cycle, may have harmful effects on living organisms. In the present work, an important contribution on the impact of multi-layer graphene (MLG) on health and environment is given by using a multifaceted approach. For the first purpose, the effect of the material on two mammalian cell models was assessed. Key cytotoxicity parameters were considered such as cell viability and inflammatory response induction. This was combined with an evaluation ofMLGtoxicity towards Xenopus laevis, used as both in vivo and environmental model organism

Diameter-dependent release of a cisplatin pro-drug from small and large functionalized carbon nanotubes

The use of platinum-based chemotherapeutic drugs in cancer therapy still suffers from severe disadvantages, such as lack of appropriate selectivity for tumor tissues and insurgence of multi-drug resistance. Moreover, drug efficacy can be attenuated by several mechanisms such as premature drug inactivation, reduced drug uptake inside cells and increased drug efflux once internalized. The use of functionalized carbon nanotubes (CNTs) as chemotherapeutic drug delivery systems is a promising strategy to overcome such limitations due to their ability to enhance cellular internalization of poorly permeable drugs and thus increase the drug bioavailability at the diseased site, compared to the free drug. Furthermore, the possibility to encapsulate agents in the nanotubes’ inner cavity can protect the drug from early inactivation and their external functionalizable surface is useful for selective targeting. In this study, a hydrophobic platinum(IV) complex was encapsulated within the inner space of two different diameter functionalized multi-walled CNTs (Pt(IV)@CNTs). The behavior of the complexes, compared to the free drug, was investigated on both HeLa human cancer cells and RAW 264.7 murine macrophages. Both CNT samples efficiently induced cell death in HeLa cancer cells 72 hours after the end of exposure to CNTs. Although the larger diameter CNTs were more cytotoxic on HeLa cells compared to both the free drug and the smaller diameter nanotubes, the latter allowed a prolonged release of the encapsulated drug, thus increasing its anticancer efficacy. In contrast, both Pt(IV)@CNT constructs were poorly cytotoxic on macrophages and induced negligible cell activation and no pro-inflammatory cytokine production. Both CNT samples were efficiently internalized by the two types of cells, as demonstrated by transmission electron microscopy observations and flow cytometry analysis. Finally, the platinum levels found in the cells after Pt(IV)@CNT exposure demonstrate that they can promote drug accumulation inside cells in comparison with treatment with the free complex. To conclude, our study shows that CNTs are promising nanocarriers to improve the accumulation of a chemotherapeutic drug and its slow release inside tumor cells, by tuning the CNT diameter, without inducing a high inflammatory response

Elucidation of the Cellular Uptake Mechanisms of Polycationic HYDRAmers

Dendrimers and dendrons appeared to potentially fulfill the requirements for being good and well-defined carriers in drug and gene delivery applications. We recently demonstrated that polycationic adamantane-based dendrons called <i>HYDRAmers</i> are easily internalized by both phagocytic and nonphagocytic cells in vitro. The aim of the present study was to investigate which of the different pathways of cellular internalization is involved in the cellular uptake of the first and second generation ammonium and guanidinium <i>HYDRAmers</i>. For this purpose, we have evaluated the internalization of fluorescently labeled <i>HYDRAmers</i> in both phagocytic murine macrophages and nonphagocytic human cervix epithelioid carcinoma cells in the presence of different well-known active uptake inhibitors. Our data revealed that the first and second generation <i>HYDRAmers</i> are internalized via different endocytic pathways based on the cellular type and on the type of functional groups present at the periphery of the dendrons. In particular, it was registered that the first generations were mainly internalized by clathrin-mediated endocytosis and macropinocytosis while the cellular internalization of the second generations was less affected by the inhibitory conditions of the endocytic pathways. These results suggest the possibility of addressing dendrimers toward specific subcellular compartments by tuning their structure properties and, in particular, the functional groups at their periphery

Polycationic adamantane-based dendrons of different generations display high cellular uptake without triggering cytotoxicity.

Dendrons used as synthetic carriers are promising nanostructures for biomedical applications. Some polycationic dendritic systems, such as the commercially available polyethylenimine (PEI), have the ability to deliver genetic material into cells. Nevertheless, polycationic vectors are often associated with potential cellular toxicity, which prevents their use in clinical development. In this context, our research focused on the design and synthesis of a novel type of polycationic dendrons that are able to penetrate into cells without triggering cytotoxic effects. We synthesized first- and second-generation polycationic adamantane-based dendrons via a combined protection/deprotection strategy starting from different adamantane scaffolds. The linker between the adamantane cores is constituted of short ethylene glycol chains, and the periphery consists of ammonium and guanidinium groups. None of these dendritic structures, which we previously called HYDRAmers, displayed significant cytotoxicity effects on two different cell lines (RAW 264.7 and HeLa). Conjugation of the fluorescent probe cyanine 5 at their focal point via click chemistry permitted the evaluation of their cellular internalization. All of the dendrons penetrated through the membrane with efficient cellular uptake depending of the dendron generation and the nature of the peripheral groups. These results suggest that the polycationic HYDRAmers are potentially interesting as new vectors in biomedical applications, including gene and drug delivery.journal articleresearch support, non-u.s. gov't2014 Jan 152014 01 03importe

Early movement restriction leads to enduring disorders in muscle and locomotion.

International audienceMotor control and body representation in the central nervous system (CNS) as well as musculoskeletal architecture and physiology are shaped during development by sensorimotor experience and feedback, but the emergence of locomotor disorders during maturation and their persistence over time remain a matter of debate in the absence of brain damage. By using transient immobilization of the hind limbs, we investigated the enduring impact of postnatal sensorimotor restriction (SMR) on gait and posture on treadmill, age-related changes in locomotion, musculoskeletal histopathology and Hoffmann reflex in adult rats without brain damage. SMR degrades most gait parameters and induces overextended knees and ankles, leading to digitigrade locomotion that resembles equinus. Based on variations in gait parameters, SMR appears to alter age-dependent plasticity of treadmill locomotion. SMR also leads to small but significantly decreased tibial bone length, chondromalacia, degenerative changes in the knee joint, gastrocnemius myofiber atrophy and muscle hyperreflexia, suggestive of spasticity. We showed that reduced and atypical patterns of motor outputs, and somatosensory inputs and feedback to the immature CNS, even in the absence of perinatal brain damage, play a pivotal role in the emergence of movement disorders and musculoskeletal pathologies, and in their persistence over time. Understanding how atypical sensorimotor development likely contributes to these degradations may guide effective rehabilitation treatments in children with either acquired (ie, with brain damage) or developmental (ie, without brain injury) motor disabilities

Polycationic Adamantane-Based Dendrons of Different Generations Display High Cellular Uptake without Triggering Cytotoxicity

Dendrons used as synthetic carriers are promising nanostructures for biomedical applications. Some polycationic dendritic systems, such as the commercially available polyethylenimine (PEI), have the ability to deliver genetic material into cells. Nevertheless, polycationic vectors are often associated with potential cellular toxicity, which prevents their use in clinical development. In this context, our research focused on the design and synthesis of a novel type of polycationic dendrons that are able to penetrate into cells without triggering cytotoxic effects. We synthesized first- and second-generation polycationic adamantane-based dendrons via a combined protection/deprotection strategy starting from different adamantane scaffolds. The linker between the adamantane cores is constituted of short ethylene glycol chains, and the periphery consists of ammonium and guanidinium groups. None of these dendritic structures, which we previously called <i>HYDRAmers</i>, displayed significant cytotoxicity effects on two different cell lines (RAW 264.7 and HeLa). Conjugation of the fluorescent probe cyanine 5 at their focal point via click chemistry permitted the evaluation of their cellular internalization. All of the dendrons penetrated through the membrane with efficient cellular uptake depending of the dendron generation and the nature of the peripheral groups. These results suggest that the polycationic <i>HYDRAmers</i> are potentially interesting as new vectors in biomedical applications, including gene and drug delivery

Carbon nanohorns allow acceleration of osteoblast differentiation via macrophage activation

Carbon nanohorns (CNHs), formed by a rolled graphene structure and terminating in a cone, are promising nanomaterials for the development of a variety of biological applications. Here we demonstrate that alkaline phosphatase activity is dramatically increased by coculture of human monocyte derived macrophages (hMDMs) and human mesenchymal stem cells (hMSCs) in the presence of CNHs. CNHs were mainly localized in the lysosome of macrophages more than in hMSCs during coculturing. At the same time, the amount of Oncostatin M (OSM) in the supernatant was also increased during incubation with CNHs. Oncostatin M (OSM) from activated macrophage has been reported to induce osteoblast differentiation and matrix mineralization through STAT3. These results suggest that the macrophages engulfed CNHs and accelerated the differentiation of mesenchymal stem cells into the osteoblast via OSM release. We expect that the proof-of-concept on the osteoblast differentiation capacity by CNHs will allow future studies focused on CNHs as ideal therapeutic materials for bone regeneration